Energy-saving, heat-insulating and noise-reducing wine cabinet glass door

By introducing an intelligent insulation mechanism and a three-layer hollow structure into the glass door of the wine cabinet, the problem of difficulty in heating and heat preservation of the glass door of the wine cabinet is solved, realizing dynamic temperature regulation and improving insulation efficiency, while enhancing sound insulation.

CN224478829UActive Publication Date: 2026-07-10ZHEJIANG JINCHEN GLASS

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
ZHEJIANG JINCHEN GLASS
Filing Date
2025-06-13
Publication Date
2026-07-10

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  • Figure CN224478829U_ABST
    Figure CN224478829U_ABST
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Abstract

The utility model relates to wine cabinet glass door technical field proposes an energy -conserving heat preservation noise reduction's wine cabinet glass door, include: door frame, set up in the glass group of door frame inside, intelligent heat preservation mechanism, set up on the door frame, wherein, intelligent heat preservation mechanism includes outer frame groove, rectangular heat preservation cotton, heating wire, controller, micro temperature sensor and fixed frame, outer frame groove opens in the outside of door frame, rectangular heat preservation cotton is bonded in the inside of outer frame groove, heating wire fixed mounting is in the inner side wall of outer frame groove, controller and micro temperature sensor opposite fixed mounting are in the inside of fixed frame. Through micro temperature sensor for detecting the temperature in the wine cabinet, when micro temperature sensor detects the temperature in the wine cabinet is lower than the temperature of setting, will information to the controller, the controller controls heating wire to start, heating wire carries out heat preservation to the inside of wine cabinet to realize according to the dynamic of wine cabinet inside and adjust temperature, effectively improve the use efficiency of wine cabinet heat preservation.
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Description

Technical Field

[0001] This utility model relates to the field of wine cabinet glass door technology, specifically to an energy-saving, heat-insulating, and noise-reducing wine cabinet glass door. Background Technology

[0002] Glass doors on wine cabinets not only showcase fine wines and enhance a family's taste, but also foster conversation among friends. Imagine friends and family visiting; the wine shelves and bottles behind the glass doors are clearly visible, naturally eliciting admiration and sparking conversation. Glass doors on wine cabinets are truly ingenious, allowing you to confidently display your wines and enhance the overall décor of your home.

[0003] For example, CN220226634U discloses an energy-saving, heat-insulating, and noise-reducing wine cabinet glass door. The glass door includes an outer layer of coated tempered glass, an inner layer of tempered glass, a sealant connecting the outer and inner layers of tempered glass to form a sealed cavity, and several interlayer supports positioned between the outer and inner layers of tempered glass to support them. This design aims to solve the technical problems of poor heat insulation, poor sound insulation, easy condensation, and high energy consumption in existing wine cabinet glass doors.

[0004] However, in implementing the relevant technology, the above-mentioned energy-saving, heat-insulating, and noise-reducing glass door for wine cabinets has the following problems: it is difficult to heat and insulate the interior of the wine cabinet, which makes it impossible to adjust the temperature according to the dynamics inside the wine cabinet, thereby reducing the efficiency of the wine cabinet's heat preservation. Therefore, an energy-saving, heat-insulating, and noise-reducing glass door for wine cabinets is proposed. Utility Model Content

[0005] This utility model proposes an energy-saving, heat-insulating, and noise-reducing glass door for wine cabinets, which solves the problem in related technologies that it is difficult to heat and insulate the interior of the wine cabinet, resulting in the inability to adjust the temperature according to the dynamics inside the wine cabinet, thus reducing the efficiency of the wine cabinet's heat preservation.

[0006] The technical solution of this utility model is as follows: an energy-saving, heat-insulating and noise-reducing glass door for a wine cabinet, comprising: a door frame, and a glass assembly disposed inside the door frame;

[0007] The intelligent insulation mechanism is installed on the door frame;

[0008] The intelligent insulation mechanism includes an outer frame groove, rectangular insulation cotton, heating wire, controller, miniature temperature sensor and fixing frame;

[0009] A sealing mechanism is installed between the glass assembly and the door frame;

[0010] The glass assembly includes an outer tempered glass layer, a Low-E coating layer, an inner laminated glass layer, a PVB sound insulation film, and a laminating layer.

[0011] Preferably, the outer frame groove is formed on the outside of the door frame, the rectangular insulation cotton is adhered to the inside of the outer frame groove, and the heating wire is fixedly installed on the inner side wall of the outer frame groove.

[0012] Preferably, the fixed frame is fixedly installed on the rear side of the door frame, and the controller and the miniature temperature sensor are fixedly installed inside the fixed frame, with the controller and the miniature temperature sensor being electrically connected.

[0013] Preferably, the Low-E coating layer is located between the outer tempered glass and the inner laminated glass. The outer tempered glass, the Low-E coating layer, and the outer side of the inner laminated glass are all covered with a PVB sound insulation film, and are fixed to the inner sidewall of the door frame by the laminated layer.

[0014] Preferably, the sealing mechanism includes an inner frame groove formed in the inner side wall of the door frame, a rectangular rubber strip bonded inside the inner frame groove, and a sealant applied between the door frame and the outer tempered glass and the inner laminated glass.

[0015] Preferably, a handle and a door lock are provided on the front side of the door frame, with the door lock located below the handle.

[0016] The working principle and beneficial effects of this utility model are as follows:

[0017] A miniature temperature sensor is used to detect the temperature inside the wine cabinet. When the miniature temperature sensor detects that the temperature inside the wine cabinet is lower than the set temperature, it transmits the information to the controller. The controller then activates the heating wire, which heats and keeps the inside of the wine cabinet warm. This allows the temperature to be adjusted dynamically according to the inside of the wine cabinet, effectively improving the efficiency of the wine cabinet's insulation. Attached Figure Description

[0018] The present invention will now be described in further detail with reference to the accompanying drawings and specific embodiments.

[0019] Figure 1 This is a schematic diagram of the overall three-dimensional structure proposed in this utility model;

[0020] Figure 2 This is a side view of the three-dimensional structure proposed in this utility model;

[0021] Figure 3 A cross-sectional three-dimensional structural diagram of the door frame is provided for this utility model;

[0022] Figure 4 This utility model proposes Figure 2 Enlarged 3D structural diagram at point A;

[0023] In the picture: 1. Door frame;

[0024] 2. Glass assembly; 201. Outer tempered glass; 202. Low-E coating layer; 203. Inner laminated glass; 204. PVB sound insulation film; 205. Lamination layer;

[0025] 3. Handle; 4. Door lock;

[0026] 10. Intelligent insulation mechanism; 101. Outer frame groove; 102. Rectangular insulation cotton; 103. Heating wire; 104. Controller; 105. Miniature temperature sensor; 106. Fixing frame;

[0027] 11. Sealing mechanism; 111. Inner frame groove; 112. Rectangular rubber strip; 113. Sealing adhesive. Detailed Implementation

[0028] The technical solutions of this utility model will be clearly and completely described below with reference to the embodiments of this utility model. Obviously, the described embodiments are only some embodiments of this utility model, and not all embodiments. Based on the embodiments of this utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the scope of protection of this utility model. Example 1

[0029] Please see Figure 1 - Figure 4 An energy-saving, heat-insulating, and noise-reducing glass door for a wine cabinet includes: a door frame 1 and a glass assembly 2 disposed inside the door frame 1;

[0030] Intelligent insulation mechanism 10 is installed on door frame 1;

[0031] The intelligent insulation mechanism 10 includes an outer frame groove 101, rectangular insulation cotton 102, heating wire 103, controller 104, miniature temperature sensor 105, and fixed frame 106. The outer frame groove 101 is opened on the outside of the door frame 1. The rectangular insulation cotton 102 is bonded to the inside of the outer frame groove 101. The heating wire 103 is fixedly installed on the inner side wall of the outer frame groove 101. The fixed frame 106 is fixedly installed on the rear side of the door frame 1. The controller 104 and the miniature temperature sensor 105 are fixedly installed inside the fixed frame 106. The controller 104 and the miniature temperature sensor 105 are electrically connected.

[0032] Glass assembly 2 includes an outer tempered glass layer 201, a Low-E coating layer 202, an inner laminated glass layer 203, a PVB sound insulation film 204, and a laminated layer 205. The Low-E coating layer 202 is located between the outer tempered glass layer 201 and the inner laminated glass layer 203. The outer tempered glass layer 201, the Low-E coating layer 202, and the outer laminated glass layer 203 are all covered with the PVB sound insulation film 204, and are fixed to the inner wall of the door frame 1 by the laminated layer 205.

[0033] This utility model provides an energy-saving, heat-insulating, and noise-reducing glass door for a wine cabinet. It consists of a three-layer hollow structure composed of an outer tempered glass 201, a Low-E coating layer 202, and an inner laminated glass 203. The outer tempered glass 201 (thickness is usually ≥5mm) has physical protection: its surface impact resistance is 3 to 5 times that of ordinary glass, preventing breakage during handling or collision. It also has thermal stability, with a temperature difference resistance >150℃, avoiding cracking caused by rapid heating and cooling (the temperature difference between the inside and outside of the glass can reach more than 40℃ when the wine cabinet is refrigerated). After breakage, it forms blunt-angled particles, avoiding personal injury.

[0034] The Low-E coating layer 202 effectively prevents infrared reflection. The nano-silver coating layer reflects more than 80% of far-infrared heat radiation (wavelength > 5μm), blocking the loss of cold air inside the wine cabinet in the form of heat radiation. Visible light transmission: maintains >70% visible light transmittance, making it easy to observe the condition of the wine bottles. The coating surface faces the inside of the hollow layer to avoid wear and improve reflection efficiency (compared to placing the coating on the outer layer, the energy-saving effect is improved by 15%).

[0035] The inner laminated glass 203 (PVB film + glass, thickness ≥ 5mm) has noise reduction capabilities. The PVB film absorbs sound wave vibration energy, blocking mid-to-high frequency noise (such as conversations and electrical appliance operation). It is safe and explosion-proof. When the glass breaks, the fragments are adhered by the PVB film to prevent shards from flying. It also blocks ultraviolet rays: the PVB layer absorbs 99% of ultraviolet rays (wavelength < 380nm), protecting the bottle label from fading.

[0036] The miniature temperature sensor 105 is used to detect the temperature inside the wine cabinet. When the miniature temperature sensor 105 detects that the temperature inside the wine cabinet is lower than the set temperature, it transmits the information to the controller 104. The controller 104 controls the heating wire 103 to start, and the heating wire 103 heats and keeps the inside of the wine cabinet warm, thereby realizing the temperature adjustment according to the dynamics inside the wine cabinet.

[0037] Furthermore, a handle 3 and a door lock 4 are provided on the front side of the door frame 1, with the door lock 4 located below the handle 3.

[0038] Specifically, handle 3 facilitates opening the glass door of the wine cabinet, and lock 4 is used to lock the glass door to the wine cabinet. Example 2

[0039] Based on Embodiment 1, this embodiment includes: a sealing mechanism 11, which is disposed between the glass assembly 2 and the door frame 1. The sealing mechanism 11 includes an inner frame groove 111 formed in the inner side wall of the door frame 1, a rectangular rubber strip 112 bonded inside the inner frame groove 111, and a sealing adhesive 113 applied between the door frame 1 and the outer tempered glass 201 and the inner laminated glass 203.

[0040] The technical solution provided in this embodiment is as follows: a rectangular rubber strip 112 is used to buffer the vibration of the outer tempered glass 201, the inner laminated glass 203 and the door frame 1, thereby achieving the purpose of noise reduction. A sealing adhesive 113 is used to seal the gap between the outer tempered glass 201, the inner laminated glass 203 and the door frame 1, effectively providing heat preservation and preventing air leakage, and further strengthening the stability of the fixation between the three.

[0041] The above are merely preferred embodiments of the present utility model and are not intended to limit the present utility model. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present utility model shall be included within the protection scope of the present utility model.

Claims

1. A wine cabinet glass door that is energy-saving, heat-insulating, and noise-reducing, characterized in that, include: Door frame (1), glass assembly (2) disposed inside the door frame (1); Intelligent insulation mechanism (10) is installed on the door frame (1); The intelligent insulation mechanism (10) includes an outer frame groove (101), rectangular insulation cotton (102), heating wire (103), controller (104), miniature temperature sensor (105) and fixed frame (106). A sealing mechanism (11) is provided between the glass assembly (2) and the door frame (1); The glass assembly (2) includes an outer tempered glass (201), a Low-E coating layer (202), an inner laminated glass (203), a PVB sound insulation film (204), and a laminated layer (205).

2. The energy-saving, heat-insulating, and noise-reducing glass door for a wine cabinet according to claim 1, characterized in that: The outer frame groove (101) is opened on the outside of the door frame (1), the rectangular insulation cotton (102) is bonded to the inside of the outer frame groove (101), and the heating wire (103) is fixedly installed on the inner side wall of the outer frame groove (101).

3. The energy-saving, heat-insulating, and noise-reducing glass door for a wine cabinet according to claim 2, characterized in that: The fixed frame (106) is fixedly installed on the rear side of the door frame (1). The controller (104) and the miniature temperature sensor (105) are fixedly installed inside the fixed frame (106) and are electrically connected.

4. The energy-saving, heat-insulating, and noise-reducing glass door for a wine cabinet according to claim 1, characterized in that: The Low-E coating layer (202) is located between the outer tempered glass (201) and the inner laminated glass (203). The outer tempered glass (201), the Low-E coating layer (202) and the inner laminated glass (203) are covered with a PVB sound insulation film (204), and are fixed to the inner wall of the door frame (1) by the laminated layer (205).

5. The energy-saving, heat-insulating, and noise-reducing glass door for a wine cabinet according to claim 1, characterized in that: The sealing mechanism (11) includes an inner frame groove (111) formed on the inner side wall of the door frame (1), a rectangular rubber strip (112) bonded inside the inner frame groove (111), and a sealant (113) applied between the door frame (1) and the outer tempered glass (201) and the inner laminated glass (203).

6. The energy-saving, heat-insulating, and noise-reducing glass door for a wine cabinet according to claim 1, characterized in that: The front side of the door frame (1) is provided with a handle (3) and a door lock (4), and the door lock (4) is located below the handle (3).